Abstract

The tracking of virtual particles is one of the main numerical tools to understand the global dispersion of marine plastic debris and has been successful in explaining the global-scale accumulation patterns of surface microplastic, often called ‘garbage patches’. Yet, the inherent inaccuracies in plastic input scenarios and ocean circulation model results produce uncertainties in particle trajectories, which amplify due to the chaotic property of the surface ocean flow. Within this chaotic system, the subtropical ‘garbage patches’ correspond to the attractor. These facts make the large scale surface ocean circulation a mixing dynamical system, which means that the information of a particle’s initial location is lost over time. We use mixing entropy and Markov chain mixing of the transfer operator associated with surface ocean transport to quantify the time scales of mixing for the global surface ocean in each subtropical basin. In the largest parts of all basins we find mixing times in the order of or below 10 years, which is lower than typical simulation times for surface plastic transport simulations. Maximum mixing times of more than 10 years are found in some parts of the North and South Pacific. Our results have important implications for global dispersion modelling of floating materials on the basin scale: precise initial information has little relevance for long term simulations, and there is a temporal limit after which the backtracking of particles is not meaningful any more.

Highlights

  • Plastic debris is very common in today’s marine environment

  • Any further distribution of this work must maintain of marine plastic debris and has been successful in explaining the global-scale accumulation patterns attribution to the of surface microplastic, often called ‘garbage patches’

  • Most of the currently existing numerical studies restrict themselves to the surface ocean, and they successfully reproduce the large scale features of surface microplastic distributions, which are the accumulation patterns in each individual subtropical gyre [8,9,10,11,12,13]

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Summary

Introduction

Plastic debris is very common in today’s marine environment. It can be found in the open ocean and on beaches, and in more remote habitats such as the polar regions and deep sea sediments [1,2,3,4]. An important tool to understand these pathways on the global scale has been numerical modelling [7], mostly Lagrangian particle tracking. Most of the currently existing numerical studies restrict themselves to the surface ocean, and they successfully reproduce the large scale features of surface microplastic distributions, which are the accumulation patterns in each individual subtropical gyre [8,9,10,11,12,13]. The high concentrations in the subtropical gyres are mainly caused by the converging Ekman currents in the subtropics [14, 15] and are often called ‘garbage patches’

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